SAGAN-II : Molecular gas content of Giant Radio Galaxies

Radio galaxies with jets of relativistic particles usually are hosted by massive elliptical galaxies with active nuclei powered by accretion of interstellar matter onto a supermassive black hole (SMBH). In some rare cases (<5%) their jets drive the overall structure to sizes larger than 700 kpc, and they are called Giant Radio Galaxies (GRGs). A very small fraction of the population of such radio galaxies contains molecular and atomic gas in the form of rings or disks that can fuel star formation. The origin of this gas is not well known, sometimes associated to a minor merger with a gas-rich disk galaxy (e.g. Centaurus A) or cooling of material from a hot X-ray atmosphere (e.g. cooling flows). The giant radio jets might be the extreme evolution of these objects, and they can teach us about the radio galaxy evolution. We have selected 12 targets from a catalogue of 820 GRGs, susceptible to be in a gas accretion and star formation phase. The targets were selected from mid-infrared to contain heated dust. We report here the results of IRAM-30m observations, the molecular gas content, the efficiency of star formation, and discuss the origin of gas and disk morphology. Most of our targets belong to the main sequence (MS), and a large fraction are in the passive domain. Their star formation efficiency is comparable to normal galaxies, except for two of them deficient in molecular gas with a short (~200 Myr) depletion time, and a quiescent gas-rich giant spiral galaxy. In general, the depletion time is much larger than the giant radio jet's life-time.